Method and system for secure printing of image

ABSTRACT

A method and system for printing an image such as a postal indicium. A sequence of graphic data blocks is formed, the sequence forming a bitmap representative of the image. The blocks are randomly reordered to form a new sequence, and the blocks are printed in the new sequence without substantial distortion. The blocks may be printed in varying directions, and the printhead may move at varying rates of travel and print at proportional rates as the blocks are printed so as to print the image without substantial distortion. The system may include a motor responsive to a programmable controller and mechanically coupled to the printhead for positioning the printhead, and the programmable controller and the motor can be enclosed in a secure housing so that no signals for controlling the motor are available outside of the housing.

This application is a divisional of application Ser. No. 10/413,978,filed Apr. 15, 2003, now U.S. Pat. No. 6,692,168 B1, which is herebyincorporated by reference.

BACKGROUND OF THE INVENTION

The subject invention relates to secure printing of images such aspostal indicia. More particularly it relates to printing images in sucha manner that printer control signal cannot easily be replicated andused to print images without accounting for them.

Recently a new way of franking mailpieces to evidence payment has beendeveloped and introduced by the assignee of the subject invention inaccordance with the Information Based Indicia Program (IBIP) of the U.S.Postal Service. Unlike previous forms of proof of payment such as stampsand postage meter indicia, IBIP indicia do not rely on details of theprinting process to provide security but instead incorporate encryptedinformation unique to each indicium which cannot be produced withoutknowledge of secret cryptographic keys. IBIP indicia have manyadvantages. For example, the information incorporated into the indicianot only provides security against counterfeit indicia, but allows thePostal Service to more closely track its operations and the needs of itscustomers. A particular advantage of IBIP and similar indicia is that,because they do not rely upon particular details of the printing processfor security, mailers can print indicia themselves with a conventionaldigital printer.

However in the case of closed system postage meters, or frankingmachines, this advantage is not fully realized since the IBIP, as wellas other International Postal Standards, require that the printer of aclosed system meter be dedicated to printing postal indicia or othermeter related information so that the printer cannot be used by a systemattacker to print postal indicia that are not accounted for by themeter. Typically this is done by the attacker recording, or otherwiserecreating, printer control data communicated to the printer, then usingthe data to drive the system printer after it is disconnected from thesystem, or to drive a similar printer.

In the past protection from such attacks has been accomplished by eitherphysically or cryptographically securing the link between the printerand the meter accounting unit (hereinafter sometimes the Postal SecurityDevice or PSD). Physical protection of the link is difficult to achieve,particularly for mutipass printers in which the printhead moves.Cryptographic protection requires encryption of the data; usingtechniques such as encrypting the printer control data, digitallysigning the data, or using message authentication codes. (Note thatcryptographic protection of the printer control data is distinct fromand in addition to any encryption of postal data which is printed aspart of the indicia.)

Thus cryptographic protection requires provision of expensivecryptographic hardware, or time consuming cryptographic software, orsome combination thereof at both ends of the PSD/printer link; whilephysical protection is, as noted, both difficult and expensive. As aresult standard off-the-shelf components cannot be used withoutsignificant modification.

Thus it is an object of the subject invention to provide a method andsystem for printing images such as postal indicia where printer controlsignals used to drive a printhead cannot be easily copied or recreatedand which can be implemented using standard printer components withoutsignificant modification.

BRIEF SUMMARY OF THE INVENTION

The above object is achieved and the disadvantages of the prior art areovercome in accordance with the subject invention by a method and systemfor forming a sequence of graphic data blocks, the sequence forming abitmap representative of the image; then randomly reordering the blocksto form a new sequence; and sequentially positioning a printhead andprinting the blocks in the new sequence, the printhead being positionedand the blocks being printed so as to print the image withoutsubstantial distortion.

In accordance with one aspect of the subject invention the blocks areprinted in varying directions.

In accordance with another aspect of the subject invention the printheadmoves are varying rates of travel and prints at proportional rates asthe blocks are printed so as to print the image without substantialdistortion.

In accordance with another aspect of the subject invention the printheadreturns to a home position after printing the image.

In accordance with still another aspect of the present invention thesystem includes a motor responsive to a programmable controller andmechanically coupled to the printhead for positioning the printhead andthe programmable controller and the motor are enclosed in a securehousing so that no signals for controlling the motor are availableoutside of the housing.

Other objects and advantages of the subject invention will be apparentto those skilled in the art from consideration of the detaileddescription set forth below and the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a schematic block diagram of a closed system postage meterin accordance with the present invention.

FIG. 2 shows a schematic representation of a postal indicium printed inaccordance with the prior art.

FIG. 3 shows a schematic representation of a postal indicium printed inaccordance with the present invention.

FIG. 4 shows a table illustrating successive printing sequences for theindicium of FIG. 3.

FIG. 5 shows a flow diagram of the operation of the meter of FIG. 1 inprinting the indicium of FIG. 3 in accordance with the presentinvention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

In FIG. 1 closed system postage meter 10 includes accounting unit 12 andprinter 14. Accounting unit 12 includes PSD 16, external interfaces 20,machine control 22, motors 24, and sensors 28. PSD 16, interfaces 20,and machine control 22 comprise programmable controller 30 whichcontrols meter 10. PSD 16 tracks available funds, generates digitalrepresentations of Indicia in accordance with IBIP or other postalstandards, accounts for postage expended, and outputs printer controldata through cable 32 to printer driver 34 in printer 12 for printingthe indicia. External interfaces 20 provide signals representative ofpostage amounts as well as other information which can be incorporatedin indicia such as dates, sequence numbers, advertising slogans, etc.Motors 24 are responsive to PSD 16 and sensors 28 to drive printhead 36in printer 12 through conventional mechanical linkage 38. Sensors 28monitor the motion of printhead 36 in a conventional manner throughconnections 40 to provide feedback to machine control 22. Except asmodified in accordance with the present invention, as will be describedfurther below, the above functions are well understood in the postagemetering art and need not be described further for an understanding ofthe present invention.

While PSD 16 and motor controller 22 have been shown as separateelements for ease of description, those skilled in the art willrecognize that they can be implemented as software functions on a singleprogrammable controller 30. More generally, the functions ofprogrammable controller 30 can be apportioned among one or moreprocessors using any convenient architecture and such choice ofarchitecture forms no part of the present invention in its broadestconception.

Typically printer 14 is an inkjet printer or the like where printhead 36is driven by print drivers 34 to print rows of print elements (i.e.dots) transverse to the direction printhead 16 travels as it is drivenby motors 24 to print the indicia generated by PSD 16. As noted above itis a particular advantage of the present invention that printer 14operates in a conventional manner and that drivers 34 and printhead 36can be standard off-the-shelf components.

FIG. 2 shows a schematic representation of a manner in which indicium 50(here represented by “INDICIUM”) can be printed in accordance with theprior art. The digital representation, or bitmap, of indicium 50 isoutput to printer 14 as two sections. Upper section U is printed asprinthead 36 moves to the left, and, after the substrate (i.e. theenvelope or label to be franked) is advanced, lower section L is printedas printhead 36 returns to the right. This sequence is the same forevery indicium. This fact greatly simplifies the task of an attacker whowishes to record the printer control data and replay it at a later time.For example, in the absence of some cryptographic or physical mechanismfor protecting the data, an attacker could record data representative ofa high value indicium, set the meter for a low value indicium,disconnect cable 32, and drive printer 14 directly with the recordeddata.

FIG. 3 shows a schematic representation of a manner in which indicium 50is printed in accordance with the present invention. Here the bitmap isoutput to printer 14 as print blocks A through H, which when printed asshown produce indicium 50 without substantial distortion. In accordancewith the present invention In accordance with the present inventionblocks A through H are printed in varying sequences and in varyingdirections, as will be described further below.

FIG. 4 shows a table giving the position, direction of travel, andstate, printing or not printing) of printhead 36 as blocks A through Hare printed in each of the sequences: BAHGFEDC, HFEDCGBA, BDCHGFEA,ABCDFHGE. The position of printhead 36 relative to the printed indiciumis shown by the letter of the zone it is over. Upper case lettersindicate that the printer 14 is printing; lower case indicates it is notprinting. Arrows “←” “→” indicate the direction printhead 36 istraveling, and arrows “↑” “↓” indicate transverse movement of printhead36 between blocks A through D and E through H.

For sequence 1, at time 0 printhead 36 is at a home position assumed tobe the right hand edge of block A. During time period 1 printhead 36moves to the left without printing to block B. During time period 2printhead 36 moves to the left and prints block B. During time period 3printhead 36 moves to the right through block B. During time period 4printhead 36 moves to the right and prints block A. At the beginning oftime period 5 printhead 36 moves downwards to the right edge of block Hand then during time periods 5 through 8 moves to the left and printsblocks H through E. At the beginning of time period 9 printhead 36 movesupwards to the left edge of block D and then during time periods 9 and10 moves to the right and prints blocks D and C. Then during timeperiods 11 and 12 printhead 36 moves to the right through blocks B and Awithout printing to return to its home position. Printing of the othersequences is substantially the same in principle; though very differentin detail.

From FIG. 4 it can be seen that there is very little commonality betweenthe various sequences. The sequences vary in length and for anyparticular time period, for different sequences print head 36 willgenerally be at different locations, moving in different directions andin different print states. As described above, this significantlyincreases the difficulty of conducting several common attacks on closedsystem postage meters since the attacker must also determine thesequence of printhead movements and control a printhead appropriately toproduce an indicium without substantial distortion.

In a preferred embodiment as shown in FIG. 4 printhead 36 returns to itshome position after printing each indium. It is believed that this willsimplify control of cumulative error in the position of printhead 36. Inother embodiments PSD 16 can calculate a path for printing an indiciumstarting from whatever position printhead 36 finishes printing of theprevious indicium.

Though time periods in FIG. 4 have been shown as constant for simplicitythey can vary. For example additional time can be provided if printhead36 moves transversely during a time period, or printhead 36 can movefaster when not printing. In other embodiments the rate of printheadtravel can vary from block to block in a manner which varies fromindicium to indicium. In one embodiment printhead 36 can travel the samepath for each indicium, e.g. ABCDHGFE, while the rate of travel variesrandomly from block to block. The print rate is varied proportionatelyso that the indicium resolution remains constant. (Print rate in dotsper second divided by travel rate in inches per second equals resolutionin dots per inch.) In other embodiments both the sequence and travelrate for printhead 36 are varied.

Returning to FIG. 1, accounting unit 12 is typically enclosed in securehousing 42 to protect against attacks based on tampering with PSD 16. Inthe preferred embodiment shown in FIG. 1 motors 24 also are physicallylocated within secure housing 42 so that no signals for driving motors24 are available outside of housing 42 for recording. In otherembodiments motors 24 can be located in printer 14 and in theseembodiments signals for driving motors 24 must be present outside ofhousing 42. These embodiments are believed to still provide asubstantial degree of security since an attacker still would facesubstantial difficulty in synchronously recording motor control signals,which are typically analog, together with the corresponding printercontrol signals.

FIG. 5 shows a flow diagram of the operation of controller 30 incarrying out the present invention. Conventional functions carried outby meter 10 which form no part of the present invention per se are notshown to simplify the disclosure. At step 60 controller 30 inputs postaldata including the postage amount and any other data necessary to definea postal indicium. At step 62 controller 30 generates a bitmaprepresentation of a postal indicium in accordance with the IBIP, orother applicable postal regulations, and partitions the bitmap intoblocks A through H as shown in FIG. 3. Generation of postal indicium iswell known in the postage meter art and need not be discussed furtherhere for an understanding of the present invention.

Returning to FIG. 1, in accordance with the present invention PSD 16incorporates random number generator 46. At step 64 in FIG. 5 controller30 accesses random number generator 46 to obtain a random number, and atstep 66 reorders blocks A through H to form a new sequence in accordancewith the random number.

At step 70 controller 30 determines if printhead 30 is ready to printthe next block in the new sequence. If so it goes to step 74. Otherwiseat step 72 it computes a path and moves printhead 36 to the next blockposition and goes to step 74.

At step 74 controller 30 determines the printhead travel rate andproportional print rate in accordance with the random number. Preferablyin such a manner that the same sequence of blocks generally will beprinted using different sequences of travel rates for differentindicium. In other embodiments of the present invention travel rates canbe constant or can vary cyclically.

At step 76 controller 30 determines if it is positioned at the left orright edge of the next block position and then goes to step 80 or step82 to print the next block accordingly. Then at step 86 controller 30determines if there is another block to be printed and if so returns tostep 70. Otherwise at step 90 controller 30 computes a path and movesprinthead 36 to its home position and exits.

The embodiments described above and illustrated in the attached drawingshave been given by way of example and illustration only. From theteachings of the present application those skilled in the art willreadily recognize numerous other embodiments in accordance with thesubject invention. Particularly though the present invention has beendescribed with respect to a preferred embodiment relating to printing ofpostal indicium it is applicable to any application where it is desiredto control and account for the printing of images. Accordingly,limitations on the subject invention are to be found only in the claimsset forth below.

What is claimed is:
 1. A method for printing a first image and a similarsecond image, said method comprising the steps of: forming a sequence ofgraphic data blocks for each of said first and second images, saidsequence forming a bitmap representative of each respective image;selecting first varying rates of travel and proportional printing ratesfor a print head to print each of said blocks in said first image;sequentially positioning the print head and printing said blocks in saidfirst image at said selected first rates of travel and said print rates;selecting second varying rates of travel and proportional printing ratesfor said print head to print each of said blocks in said second image,said second rate of travel for a block of said second image beingdifferent than said first rate of travel for a corresponding block ofsaid first image; and sequentially positioning the print head andprinting said blocks in said second image at said selected second ratesof travel and said print rates.
 2. The method of claim 1, wherein thefirst rate of travel is different for each of said blocks in said firstimage.
 3. The method of claim 1, wherein the first rate of travel is thesame for at least two blocks in said first image.
 4. The method of claim1, wherein the first and second images are indicium.
 5. The method ofclaim 1, wherein the print head positioning for the first image isidentical to the print head positioning for the second image.
 6. Themethod of claim 1, wherein the print head positioning for the firstimage is different than the print head positioning for the second image.7. The method of claim 1, further comprising: randomly reordering saidblocks in at least one of said first and second image to form a newsequence; and sequentially positioning the print head and printing saidblocks in said new sequence at said selected rates of travel and saidprint rates for said at least one of said first and second image.